source: src/libcfa/concurrency/thread.c @ d807ca28

//
// Cforall Version 1.0.0 Copyright (C) 2016 University of Waterloo
//
// The contents of this file are covered under the licence agreement in the
// file "LICENCE" distributed with Cforall.
//
// thread.c --
//
// Author           : Thierry Delisle
// Created On       : Tue Jan 17 12:27:26 2017
// Last Modified By : Peter A. Buhr
// Last Modified On : Fri Mar 30 17:19:52 2018
// Update Count     : 8
//

#include "thread"

#include "kernel_private.h"

#define __CFA_INVOKE_PRIVATE__
#include "invoke.h"

extern "C" {
        #include <fenv.h>
        #include <stddef.h>
}

//extern volatile thread_local processor * this_processor;

//-----------------------------------------------------------------------------
// Thread ctors and dtors
void ?{}(thread_desc & this, const char * const name, cluster & cl, void * storage, size_t storageSize ) with( this ) {
        self_cor{ name, storage, storageSize };
        verify(&self_cor);
        curr_cor = &self_cor;
        self_mon.owner = &this;
        self_mon.recursion = 1;
        self_mon_p = &self_mon;
        curr_cluster = &cl;
        next = NULL;

        node.next = NULL;
        node.prev = NULL;
        doregister(curr_cluster, this);

        monitors{ &self_mon_p, 1, (fptr_t)0 };
}

void ^?{}(thread_desc& this) with( this ) {
        unregister(curr_cluster, this);
        ^self_cor{};
}

forall( dtype T | sized(T) | is_thread(T) | { void ?{}(T&); } )
void ?{}( scoped(T)& this ) with( this ) {
        handle{};
        __thrd_start(handle);
}

forall( dtype T, ttype P | sized(T) | is_thread(T) | { void ?{}(T&, P); } )
void ?{}( scoped(T)& this, P params ) with( this ) {
        handle{ params };
        __thrd_start(handle);
}

forall( dtype T | sized(T) | is_thread(T) )
void ^?{}( scoped(T)& this ) with( this ) {
        ^handle{};
}

//-----------------------------------------------------------------------------
// Starting and stopping threads
forall( dtype T | is_thread(T) )
void __thrd_start( T& this ) {
        coroutine_desc* thrd_c = get_coroutine(this);
        thread_desc   * thrd_h = get_thread   (this);
        thrd_c->last = TL_GET( this_coroutine );

        // __cfaabi_dbg_print_safe("Thread start : %p (t %p, c %p)\n", this, thrd_c, thrd_h);

        disable_interrupts();
        create_stack(&thrd_c->stack, thrd_c->stack.size);
        kernelTLS.this_coroutine = thrd_c;
        CtxStart(&this, CtxInvokeThread);
        assert( thrd_c->last->stack.context );
        CtxSwitch( thrd_c->last->stack.context, thrd_c->stack.context );

        ScheduleThread(thrd_h);
        enable_interrupts( __cfaabi_dbg_ctx );
}

extern "C" {
        // KERNEL ONLY
        void __finish_creation(void) {
                coroutine_desc* thrd_c = kernelTLS.this_coroutine;
                ThreadCtxSwitch( thrd_c, thrd_c->last );
        }
}

void yield( void ) {
        // Safety note : This could cause some false positives due to preemption
      verify( TL_GET( preemption_state.enabled ) );
        BlockInternal( TL_GET( this_thread ) );
        // Safety note : This could cause some false positives due to preemption
      verify( TL_GET( preemption_state.enabled ) );
}

void yield( unsigned times ) {
        for( unsigned i = 0; i < times; i++ ) {
                yield();
        }
}

// KERNEL ONLY
void ThreadCtxSwitch(coroutine_desc* src, coroutine_desc* dst) {
        // set state of current coroutine to inactive
        src->state = src->state == Halted ? Halted : Inactive;
        dst->state = Active;

        // set new coroutine that the processor is executing
        // and context switch to it
        kernelTLS.this_coroutine = dst;
        assert( src->stack.context );
        CtxSwitch( src->stack.context, dst->stack.context );
        kernelTLS.this_coroutine = src;

        // set state of new coroutine to active
        dst->state = dst->state == Halted ? Halted : Inactive;
        src->state = Active;
}

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